Adsorbent breather filter

ABSTRACT

The invention relates to a device for filtering contaminants, such as particulates and vapor phase contaminants, from a confined environment such as electronic or optical devices susceptible to contamination (e.g. computer disk drives) by improving performance and possibly incorporating multiple filtration functions into a unitary filter. The filter includes flow layers which improve filter performance. Filtration functions include a passive adsorbent assembly and can include a combination of inlet, or breather filter and adsorbent filter. Moreover, recirculation filter, diffusion tube and outside mount functions can be added to the filter depending on desired functionality within the enclosure.

FIELD

This invention relates to a device for filtering contaminants, such as particulates and vapor phase contaminants, from a confined environment such as electronic or optical devices susceptible to contamination (e.g. computer disk drives). Specifically, the filter assembly filters contaminates from the inlet air as well as contaminates that are generated from within the device.

BACKGROUND

Many enclosures that contain sensitive equipment must maintain very clean environments in order for the equipment to operate properly. Examples include enclosures for the following: optical surfaces or electronic connections that are sensitive to particulates and gaseous contaminants which can interfere with mechanical, optical, or electrical operation; data recording devices, such as computer hard disk drives that are sensitive to particles, organic vapors, and corrosive vapors; processing and storage of thin films and semiconductor wafers; and electronic controls such as those used in automobiles and industrial applications that can be sensitive to particles, moisture buildup and corrosion as well as contamination from fluids and vapors. Contamination in such enclosures originates from both inside and outside the enclosures. For example, in computer hard drives, damage may result from external contaminates as well as from particles and vapors generated from internal sources. The terms “hard drives” or “hard disk drives” or “disk drives” or “drives” will be used herein for convenience and are understood to include any enclosure for equipment or material that is sensitive to contamination.

Disk drives must be protected against a large number of contaminants that are found in the surrounding environment and can penetrate the drive. This is particularly true for drives that are removable and portable to any environment such as disk drives that are used in laptop computers or in Personal Computer Memory Card International Association (PCMCIA) slots, or other drives which may not be used in the typical data processing environment. Drives used in applications such as gaming systems, personal video recorders, automotive mapping systems and others must survive in environments that are more severe than that of standard desk top computer applications.

Contamination may occur in various forms. For example, disk drives are susceptible to corrosive ions, such as chlorine and sulfur dioxides, and may also be sensitive to variations in humidity. Accordingly, an array of failure mechanisms exist.

One serious contamination-related failure mechanism in computer disk drives is static friction or “stiction.” Stiction results from the increased adhesion of a drive head to a disk while the disk is stationary plus increased viscous drag parallel to the head-disk interface. Newer high-density disks are more sensitive to contamination-caused stiction because they are smoother and include relatively thin layers of lubricants. Contaminants on the disk change the surface energy and increase the adhesive forces between the head and disk, causing stiction. Also, stiction may be caused by vapors condensing in the gap between the head and disk. The low energy low torque motors that are being used in smaller disk drives for portable computers and the low noise drives used in other applications, such as personal video recorders, are increasingly sensitive to stiction related failures.

Another serious contamination-related failure mechanism is a head crash. Head crashes can occur when particles get into the head disk interface. The spacing or flying heights between the head and disk during operation of modern high density drives is 30 nanometers or less. As rotational speed affects the maximum data transfer rate a drive can have, rotational speed of modern disk drives is increasing. Some current drives operate at 15,000 revolutions per minute and future drives will likely use even higher speeds. With such high speeds and low flying heights, even submicron-sized particles can be a problem, causing the head to crash into the particle or the disk after flying over a particle, bringing the drive to an abrupt failure mode. Particles can also adversely affect data integrity and mechanical reliability of a drive, sometimes referred to as thermal asperity.

Disk Drives are also susceptible to variances in humidity. Low humidity is problematic either because it may increase static electricity or decrease lube thickness or functionality. However, in high humidity, corrosion is promoted and lubricants may swell. It takes significantly more adsorbent to protect a drive from humidity than it does from organic or acid gas contamination. Thus drives that need buffering from humidity fluctuations require significant amounts of adsorbent.

To prevent contamination-related failure, a variety of filtration devices have been used. For example, filtration devices to keep particles from entering disk drives are well known. Some consist of a filtration media held in place by a housing of polycarbonate, acrylonitrile butadiene styrene (ABS), or some other material. Others consist of a filtration media in the form of a self-adhesive disk utilizing a layer or layers of pressure sensitive adhesive. Such filters are mounted and sealed over a vent hole in the enclosure to filter particulates from the air entering the drive. Filtration performance depends not only on the filter media having a high filtration efficiency but also on having it have a low resistance to airflow. If the pressure drop is too high, unfiltered air will leak into the enclosure through a gasket, screw hole, or other seam instead of entering through the filter. Such filters may work well for particulates of external origin, but do not address the problems from vapor phase contaminants.

Internal particulate filters, or recirculation filters, are also well known. These filters are typically pieces of filter media, such as expanded PTFE membrane laminated to a polyester nonwoven backing material. Other recirculation filters are “pillow-shaped” filters containing electret (i.e., electrostatic) filter media. These filters may be pressure fit into slots or “C” channels and are placed in an active air stream such as near the rotating disks in a computer hard disk drive or in front of a fan in electronic control cabinets, etc. Alternatively, the recirculation filter media can be held in a plastic frame. Still alternatively they can be applied to the sides of components or the housing to allow for particle collection. Recirculation filters work well for particulate removal of internally generated particles but do not address the problem of vapor phase contaminants, nor do they provide protection from external particles entering the drive.

Internal adsorbent filters are also well known. One example is described in U.S. Pat. No. 4,830,643 issued to Sassa et al. This patent teaches a sorbent filter where a powdered, granular or beaded sorbent or sorbent mixture is encapsulated in an outer expanded PTFE tube. This filter is manufactured by W. L. Gore & Associates, Inc., Elkton, Md., and is commercially available under the trademark GORE-SORBER® module. A second well known internal adsorbent assembly is described in U.S. Pat. No. 5,593,482 issued to Dauber et al. A third internal adsorbent assembly incorporates a layer of adsorbent such as activated carbon/PTFE composite between two layers of filter media or is alternately wrapped in a layer of filter media and can be installed between slots or “C” channels much the way a recirculation filter is installed but without significant airflow through the filter. Such a filter is described in U.S. Pat. No. 5,500,038 issued to Dauber et al.

Known internal adsorbent filters work well at adsorbing vapor phase contaminants, but they do not filter particulates very well. They may collect particles by some impaction of particles onto the filter (i.e., by having the larger particles impacting or colliding with the adsorbent filter as particle-laden air speeds around the filters) or by diffusion of particles onto the filter. However, these filters do not perform nearly as well as the standard recirculation filters, which work by a combination of sieving (mechanically capturing particles too large to pass through the pore structure of the filter), impaction (capturing particles too large to follow the bending air streams around filters or the fibers of the filter), interception (capturing particles that tend to follow the air streams, but are large enough to still intercept a filter fiber or in other words those particles with a diameter equal to or less than the distance between the fiber and the air stream line), and diffusion (capturing smaller particles buffeted about by air molecules in a random pattern and coming into contact with a filter fiber to become collected).

Because there is a need to remove vapor phase contaminates as well as particles from both internal and external sources, combination sorbent breather filters were developed. These can be made by filling a cartridge of polycarbonate, ABS, or similar material with sorbent and securing filter media on one or both ends of the cartridge and placing the cartridge over a hole in the container wall. These filters effectively cleanse incoming air of particles and vaporous contaminates, and internal air of internally generated vaporous contaminates. Because the filters are inside, the vaporous drive contaminate will diffuse into the adsorbent sections of the filters. Examples of such filters are described in U.S. Pat. No. 4,863,499 issued to Osendorf (an anti-diffusion chemical breather assembly for disk drives with filter media having a layer impregnated with activated charcoal granules); U.S. Pat. No. 5,030,260 issued to Beck et al. (a disk drive breather filter including an assembly with an extended diffusion path; U.S. Pat. No. 5,124,856 issued to Brown et al. (a unitary filter medium with impregnated activated carbon filters to protect against organic and corrosive pollutants); and U.S. Pat. No. 5,447,695 issued to Brown et al. (Chemical Breather Filter Assembly). Unfortunately, many of these designs are too large and take up too much space in today's miniaturized drives.

To adsorb corrosive compounds such as chlorine and sulfur dioxide, an adsorbent is typically treated with a salt to chemisorb the contaminants. However, when many known filters are washed in deionized water, large amounts of these salts may be released, which makes them unacceptable in sensitive disk drive environments.

A washable adsorbent recirculation filter is described in U.S. Pat. No. 5,538,545 issued to Dauber et al., wherein expanded PTFE membranes or other hydrophobic materials are used to encapsulate the adsorbent. However, these filters do not filter air as it comes into the drive before it has had a chance to deposit particles and do damage to the drive.

A second combination adsorbent breather filter is also well known that encapsulates the adsorbent material such as an impregnated activated carbon polytetrafluoroethylene (PTFE) composite layer between two layers of filter media and is applied over a hole in the enclosure with a layer of pressure sensitive adhesive. These filters work well to an extent and are of a size that can be used in today's small drives and are typically designed to filter air coming into the drive. Thus, the adsorbent is typically primarily designed to adsorb both organic and corrosive vapors from the outside environment and will filter particulates only from air coming into or leaving the drive. Internally generated vapors and moisture can be adsorbed by these filters, but often times they have been used in conjunction with another larger internal adsorbent filter so the adsorbent breather filter can be smaller in size. Therefore, such filters may not contain enough adsorbent to adequately adsorb all the internally generated contaminants and typically will not contain enough adsorbent to control humidity well within the drive as previously mentioned. Again, particles are also generated inside the drive and are not typically captured by these filters.

Combinations of several filters having different functions in a single drive have been taught. For example, U.S. Pat. No. 5,406,431, to Beecroft, describes a filter system for a disk drive that includes an adsorbent breather and recirculation filter in specifically identified locations within the drive. Also, U.S. Pat. No. 4,633,349, by Beck et al., teaches a disk drive filter assembly comprising a dual media drum type filter element in a recirculating filter assembly that surrounds a breather filter. Further, U.S. Pat. No. 4,857,087, to Bolton et al., teaches incorporating a breather filter in a recirculation filter housing, but has significantly more parts and incorporates a third filter element complete with housings, apertures, and gaskets to accomplish this inclusion. The combinations described in these patents either locate the filter components in separate regions of the disk drive or incorporate space-consuming fixtures to orient the component parts within the drives.

Space saving combinations having further multifunctionality have also been taught. These include U.S. Pat. No. 6,266,208 to Voights integrating a recirculation filter, breather filter, and adsorbent filter into a single unitary filter; U.S. Pat. No. 6,238,467 to Azarian et al., incorporating a breather filter, adsorbent filter, and recirculation filter into a rigid assembly filter; U.S. Pat. No. 6,296,691 to Gidumal incorporating a breather filter adsorbent filter and recirculation filter into a molded filter; and U.S. Pat. No. 6,395,073 to Dauber incorporating the recirculation filter and breather filter with optional adsorbent filter into a low profile adhesive construction. All but the last filter design by Dauber are filters of considerable size and are not appropriate for smaller drives like the 2.5″ laptop drives and smaller 1.8″ drives, 1.0″ drives and 0.85″ drives that are currently in the market and/or in design.

As disk drives have become smaller and less expensive, there is a need for simplification and the reduction in the number of parts in a drive to reduce cost and improve performance. However, as the drives increase in recording data density and capacity, they become more sensitive to particulate and vaporous contamination including increased sensitivity to moisture.

Existing filtration means often do not meet these demanding filtration requirements. The low profile adsorbent breather filters and low profile multifunction filters best suited in size to fit these smaller drives have had to compromise in adsorbent content because they needed airflow through the filter. The compromise has been to either use very dense adsorbent media and have limited airflow, or use less dense adsorbent media to maintain airflow but then have limited adsorbent capacity. Two recent inventions have tried to overcome this deficiency. U.S. Pat. No. 6,683,746 to Kuroki et. al. allows for air by-pass of the adsorbent media to increase airflow, but can have performance reductions in adsorption if too much air by-passes the adsorbent media. U.S. Pat. No. 6,712,887 to Ueki et. al. uses grooves in the adsorbent media to increase airflow, but this has limited functionality as there are further limitations to airflow through the filtration layer unaddressed by this invention.

SUMMARY

In one aspect, the invention is an adsorbent breather assembly for removing contaminants within an enclosure having a fluid inlet/outlet port comprising: an adhesive layer; an adsorbent media adjacent to the adhesive layer, in which the adsorbent media has at least a bottom surface and a top surface, and the adsorbent media is in fluid communication with the fluid inlet/outlet port; a flow layer is adjacent to at least one surface of the adsorbent media and a filter media attached to the adhesive layer such that the adsorbent media and the flow layers are encapsulated between the adhesive layers and the filter media.

In still another aspect, the invention provides an adsorbent having a bottom surface adjacent to a layer of adhesive.

In still another aspect, the invention provides an adsorbent layer having a bottom surface adjacent to the flow layer which is in turn adjacent to the adhesive.

In yet another aspect, the invention provides a filter media comprising a porous polymeric membrane. In this aspect, the porous polymeric membrane is preferably hydrophobic. More preferably, the porous polymeric membrane comprises PTFE.

In another aspect, the invention provides a filter that includes an electret particle filtering layer disposed on a porous polymeric membrane.

An another aspect the invention provides a filter media comprising an electret layer.

In still another aspect, the invention provides an adsorbent media comprising PTFE and an adsorbent material. In this aspect, the adsorbent media preferably comprises a PTFE membrane filled with an adsorbent material.

In yet another aspect, the invention provides a molded adsorbent media.

In a further aspect, the invention provides an adsorbent media including a non-woven fabric impregnated with an adsorbent.

In another aspect, the invention provides an adsorbent media including a granular material disposed on at least one side of a fiber scrim.

In still another aspect, the invention provides an adsorbent media including a physisorbent. In this aspect, the physisorbent is preferably selected from the group consisting of activated carbon; activated alumina; molecular sieves; silica gel and combinations thereof.

In yet another aspect, the invention provides an adsorbent media comprises a chemisorbent. In this aspect, the chemisorbent is preferably a material impregnated with at least one material selected from the group consisting of potassium permanganate, calcium carbonate, potassium carbonate, potassium hydroxide, sodium carbonate and calcium sulfate; and combinations thereof.

In a further aspect, the invention provides an adsorbent media having at least one side surface wherein at least one flow layer is adjacent to a side surface, the top surface, or the bottom surface of the adsorbent media.

In another aspect, the invention provides a flow layer including two or more grooves. In this aspect, the grooves may be parallel, form a radial pattern or intersect.

In still another aspect, the invention provides an adsorbent breather assembly in which the flow layer is porous.

In yet another aspect, the invention provides an adsorbent breather assembly in which the flow layer comprises a discontinuous pattern of adhesive.

In a still further aspect, the invention provides an adsorbent breather assembly in which the flow layer is about 0.5 mils to about 50 mils thick.

In another aspect, the invention provides an adsorbent breather assembly in which the flow layer is about 10 mils to about 25 mils thick.

In yet another aspect, the invention provides an adsorbent breather assembly in which the flow layer is about 10 mils to about 20 mils thick.

In still another aspect, the invention provides an adsorbent breather assembly in which the flow layer comprises an impermeable material having grooves on at least one surface

In another aspect, the invention provides an adsorbent breather assembly wherein the adsorbent media comprises two or more layers.

In yet another aspect, the invention provides an adsorbent breather assembly in which the adsorbent includes a first layer having at least one flow layer and a second adsorbent layer adjacent to the flow layer of the first adsorbent layer. In this aspect another flow layer may be adjacent to the second adsorbent layer.

BRIEF DESCRIPTION OF THE DRAWINGS

The operation of the present invention should become apparent from the following description when considered in conjunction with the following drawings, in which:

FIG. 1 is a top view of an embodiment of the filter unit of the present invention as it would be located on a drive housing;

FIG. 2 is a side cross-sectional view of an embodiment of the filter unit of the present invention, as it would appear on the enclosure housing;

FIG. 3 is a side cross-sectional view of a computer hard disk drive showing an embodiment of the filter unit of the present invention installed therein;

FIGS. 4A and 4B are side cross-sectional and top views, respectively, of an embodiment of the filter unit of the present invention having flow layers adjacent to the top and bottom surfaces of the adsorbent;

FIGS. 5A and 5B are side cross-sectional and top views, respectively, of another embodiment of the filter unit of the present invention having flow layers adjacent to the side and bottom surface of the adsorbent layer;

FIGS. 6A and 6B are side cross-sectional and top views, respectively, of another embodiment of the filter unit of the present invention having flow layers adjacent to the top, bottom, and sides of the adsorbent layer;

FIGS. 7-10 are side cross-sectional views of flow layers according to embodiments of the invention showing groove patterns on the flow layers;

FIGS. 11A and 11B are side cross-sectional and top views respectively of another embodiment of the present invention including a diffusion tube within the construction of the filter element.

FIG. 12 is a side cross-sectional view of another embodiment of the present invention showing the filter element in an outside mount configuration.

FIGS. 13 and 13B are side cross-sectional and top views respectively of another embodiment of the present invention showing the filter in an outside mount configuration with a diffusion tube within the construction of the filter element;

FIG. 14 is a side cross-sectional view of another embodiment including a recirculation filter included within the filter construction;

FIG. 15 is a side cross sectional view of another embodiment with a filler or gasket around the filter that is countersunk into the drive baseplate such that the assembled filter and gasket are level with the drive baseplate.

FIGS. 16A and 16B are side cross-sectional and top views of another embodiment where a top perimeter groove in the adsorbent is used along with a bottom flow layer.

FIGS. 17A and 17B are side cross-sectional and top views of another embodiment in which the adsorbent comprises multiple layers of adsorbent material with a flow layer disposed between the two layers as well as on the top of the first or top adsorbent layer and on the bottom of the second or bottom adsorbent layer.

DETAILED DESCRIPTION

The adsorbent breather filters of the present invention include an adsorbent disposed on a mounting adhesive layer, and a filter layer covering the adsorbent. A flow layer adjacent to at least one of the surfaces of the adsorbent improves filter performance. The filter layer encapsulates the adsorbent and the flow layer between the filter media layer and the mounting adhesive layer. Preferably, the mounting adhesive layer also attaches the filter to the drive.

The present invention consolidates filtration functions which were often performed by two, three, or more filters into a single filter that functions well, is easy to install, is clean and cleanable. Moreover, as one of skill in the art will readily appreciate, further components, such as a gasket or gasket(s) or vibration dampening materials, can be included to further reduce the number of components required for final assembly. Common to all embodiments of the invention is the highly dense adsorbent media combined with at least one flow layer to allow good airflow while maintaining maximum adsorbent capacity and good adsorbent performance.

The filter may comprise a layer or layers of adhesive to attach the filter to the proper location on the interior or exterior of the drive enclosure wall. The filter may optionally cover an inlet diffusion tube or channel in the drive housing, or the filter may fully contain a diffusion tube. A layer of filter media to filter the incoming air of particles is provided in substantially laminar relation to the adhesive. An optional layer or layers of filter media can be provided to filter recirculating air. A layer or layers of adsorbent media is provided to filter one or both of the incoming and recirculating air streams of vaporous contaminants. Appropriate partitioning of the filter is provided to permit flow channels for inlet air and for recirculating air without the possibility of allowing unfiltered inlet air through the filter.

The adsorbent may comprise one or more layers of 100% adsorbent materials, such as granular activated carbon, or may be a filled product matrix such as a scaffold of porous polymeric material compounded with adsorbents that fill the void spaces. Other possibilities include adsorbent impregnated nonwovens or adsorbent beads on a scrim where the non-woven or scrim may be cellulose or polymeric and may include latex or other binders as well as porous castings or tablets of adsorbents and fillers that are polymeric or ceramic. The adsorbent can also be a mixture of different types of adsorbents.

Suitable adsorbents include: physisorbers (e.g. silica gel, activated carbon, activated alumina, molecular sieves, etc.); chemisorbers (e.g. potassium permanganate, potassium carbonate, potassium hydroxide, potassium iodide, calcium carbonate, calcium sulfate, sodium carbonate, sodium hydroxide, calcium hydroxide, powdered metals or other reactants for scavenging gas phase contaminants); as well as mixtures of these materials. For some applications, it may be desirable to employ multiple layers of adsorbent materials, with each layer containing different adsorbents to selectively remove different contaminants as they pass through the filter or as they may be exposed from inside the enclosure.

Preferably, the adsorbent utilizes an adsorbent-filled PTFE membrane wherein adsorbent is entrapped within the reticular PTFE structure as taught by U.S. Pat. No. 4,985,296 issued to Mortimer, Jr. and specifically incorporated herein by reference. As used herein, a membrane includes thin sheets, tapes or films of polymeric material. Most preferably, particles are packed in a multi-modal (e.g. bi-modal or tri-modal) manner with particles of different sizes interspersed around one another to fill as much of the available void space between particles as is possible, so as to maximize the amount of active material contained in the core. This technique also allows a number of sorbents to be filled into a single layer. The core can then be compressed or layered and compressed to attempt to maximize adsorbent loading and density. Previously air flow was required through the adsorbent and expanding of the material was required to allow for airflow, but with this invention, high density adsorbent materials are combined with flow layers on one or more surfaces of the adsorbent to allow for good airflow, good adsorbent performance and maximum adsorbent loading and density.

Another preferred embodiment of the adsorbent layer that can be used in the present invention is discussed in detail in Japanese Laid-Open Patent Application (Kokai) Number 4-323007.

In one aspect, the invention includes at least one flow layer adjacent to the adsorbent. As used herein, a “flow layer” is intended to mean a material that allows the passage of gas through pores or interstices. A flow layer may be constructed of any porous material. Alternatively, a flow layer may be constructed of non-porous materials shaped or formed to provide interstices for gas flow channels within or adjacent to the flow layer. The gas flow channels may be random or of any configuration or pattern. For example, the pattern may be linear; consisting of either parallel or intersecting grooves in the surface of the flow layer, and may also be radial and may be centered about an inlet port for a drive.

Alternately, a flow layer may comprise a layer of patterned adhesive. As used herein, a “patterned adhesive” is a layer of adhesive that is discontinuous, or has gaps within the layer exposing the underlying substrate. Such a discontinuous layer may be in the form of patterned adhesive lines, which are either parallel or intersecting. In another aspect, the patterned adhesive may be in the form of a matrix of adhesive dots spaced at random or regular intervals. Alternatively, a matrix consisting of adhesive dots could be applied to make a crosshatched pattern. The patterned adhesive may be zone or strip coated onto a carrier. In yet another alternative, a zone or strip coat of adhesive is applied to the filter membrane or to the adsorbent.

The flow layers allow for improved airflow over the adsorbent material surface, which results in greater filtration and adsorbent performance. Due to improved surface airflow, it is not necessary that the air flow through the adsorbent media. Using flow layers reduces the pressure drop across the filter. Accordingly, the flow layers, and the surface flow paths provided thereby, permit high-density adsorbent materials to be used.

In the embodiments described and illustrated herein, the adhesive layer is typically a mounting adhesive layer for mounting the filter to the enclosure wall. However, the adhesive layer may have different constructions. It can be a single layer of transferable adhesive, a single sided adhesive coated onto a carrier or substrate such as polyester or polyethylene or a double-sided adhesive coated onto a carrier or substrate as described within the illustrations.

The selection of an adhesive is not critical. However, the adhesive must have a high enough peel strength to withstand application use and meet any use specifications that may exist such as high temperature, solvent resistance, FDA approval, repositionable, or low outgassing specifications. Selection of an appropriate adhesive is understood by one of skill in the art. A typical low outgassing specification is to pass ASTM E-595-84 specification of less than 1% total mass loss and 0.1% collected volatile condensable material. A preferred embodiment utilizes one layer of 0.001″ (0.0025 cm) thick permanent acrylic pressure sensitive adhesive applied to the outer side of the film and a second layer of double-sided permanent acrylic pressure sensitive adhesive 0.004″ (0.010 cm) thick for the inner most adhesive which contacts the filter material and adsorbent. This adhesive has medium to high peel strengths in excess of 20 ounces/inch as measured by PSTC #1 (FTMI) and passes outgassing ASTM E-595-84 specification. A commercially available transfer adhesive is [3M 9457] and a commercially available double-sided adhesive is [3M 415] which both employ an A-40 acrylic adhesive all commercially available from Minnesota Mining Manufacturing, Inc. of Minneapolis, Minn.

Other adhesives, such as hot melt adhesives, thermoset and thermoplastic adhesives, UV curable adhesives, or other curable adhesives, epoxies and other reactive adhesives, etc. are also suitable. Furthermore, if a diffusion tube is desired, adhesives as described in U.S. Pat. No. 5,417,743, the disclosure of which is hereby incorporated by reference, can be used. For example in many of the examples illustrated above incorporating a diffusion tube, a second adhesive layer is superimposed over the first. This second layer could again be just adhesive, but a single-sided (i.e., adhesive on one side of a carrier or substrate) or double-sided adhesive is preferred for ease in handling and processing.

Prior to attachment to the disk drive housing, the exposed adhesive layers may have one or more release liners adhered thereto to protect the adhesive and to facilitate handling of the filters. The release liners would be removed prior to assembly of the filter onto the disk drive enclosure.

PTFE membrane filter materials can be used to cover the adsorbent material and act as filtration membranes. One such preferred filter media to encapsulate the adsorbent layer is a layer of expanded PTFE membrane made in accordance to U.S. Pat. No. 4,902,423 issued to Bacino et al. and incorporated herein by reference. This filter media may be structurally supported by a layer of woven, nonwoven, or expanded porous material, such as polyester, polypropylene, polyamide, etc. This filter media has several advantages. It can be made very highly permeable, with resistances to air flow of less than 0.5 mm H₂O @ 10.5 feet per minute (3.2 meters per minute) and still contain adsorbent particulate within the filter.

The particle filtration efficiency of this highly expanded membrane as measured on a TSI 8160 efficiency test rig available from TSI Inc., in Minnesota, is also very good (e.g. in excess of 55% at 0.3 μm) which provides good particle filtration along with the adsorbent containment. A preferred support layer is a Reemay 2014 polyester nonwoven, 1.0 oz/yd² available from Reemay, Inc., Old Hickory, Tenn.

A second preferred filter media to cover or encapsulate the adsorbent layer is a layer of an electrostatic triboelectret material available in finished filter form from W. L. Gore and Associates, Inc. under the trademark GORE-TRET® recirculation filters. An illustrated example of this would be layer 67 in FIG. 14. Advantages of this media are that it is very high in efficiency (e.g., in excess of 90% @ 0.3 micron) and also very permeable (e.g., less than 1 mm H₂O at 10.5 fpm or 3.2 m/min). While this media loses its charge while being washed with deionized water, it immediately regains its efficiency upon drying due to the triboelectric effect of the mix of dissimilar fibers.

Other filter materials can also be used. They could be other electrets or other triboelectret materials that yield high efficiencies and low resistances to airflow. They could also be other filter papers or filter membranes such as polypropylene membranes or cast polymeric membranes or some combination of filter materials. Different filter materials with different properties can be used in the different embodiments of the invention wherever filter layers are used and/or optionally used depending upon the required performance needed.

An outer protective layer can also be used to add durability to the filter and to contain any protruding fibers from either the triboelectret type filter media or the filter support media for the membrane filter media. Typically, this would be an extruded or expanded plastic material such as polypropylene, polyethylene, polyamide, polyester, etc. A preferred material is a Delnet 0707 expanded polypropylene material available from DelStar Technology, Inc., Middletown, Del.

Using PTFE membranes as a filter material over the adsorbent layers imparts a number of additional advantages to this improved filter construction. First, PTFE is hydrophobic. Some adsorbents used in the industry use a water-soluble salt to impregnate a physical adsorbent such as activated carbon to provide a chemical adsorbent with a large active surface area. However, the water-soluble chemi-sorbent salts are removed if the filter is washed. By covering the carbon layer with the PTFE membrane, the final part is waterproof and washable; water can come into contact with the part and not penetrate the adsorbent.

Washability is important because ionic contamination is a major concern for corrosion susceptible apparatus such as computer disk drives. Ions of concern, such as chlorine and sulfur dioxide, are readily soluble in water, so washing with deionized water has become routine for many components used within a drive. Also, reworking of drives that initially fail certification is common in the industry and often washing the drive housing is included in reworking. Thus, embodiments utilizing PTFE filter layers to encapsulate the adsorbent allows use of water soluble, salt treated adsorbents and can withstand washing without losing adsorbent effectiveness. And reworking can be done without having to remove the adsorbent filter from the housing.

Filters in accordance with the present invention are not only low in particulation, outgassing, and nonvolatile residues, the filters may also be washable. Washing with deionized water to remove surface ionic contamination and particulation improves the filters' suitability for those applications requiring such cleanliness, such as in computer disk drives. The filters may be washed without washing out beneficial treatments such as salts, which remove acid gases from the air streams. This washability is accomplished by using hydrophobic filter materials (along with impermeable layers such as adhesives, etc.) to surround the adsorbent layers. “Hydrophobic” as used in this application means the filter materials have a water (or water with surfactant if one is used) entry pressure sufficient to withstand the conditions of conventional washing steps, such as heating, stirring, ultrasonics, etc.

While the PTFE membranes mentioned above are hydrophobic and can be washed, they also have a high vapor transmission rate, which allows contaminants in the air to quickly and easily diffuse through the membranes into the adsorbents. PTFE membranes can also be made with very good filtration efficiencies, which is especially beneficial in the breather filter and adsorbent breather filter applications. An exemplary membrane could be made in accordance with U.S. Pat. No. 3,953,566. Such a membrane can have a filtration efficiency of 99.97% at 0.3 microns sized particles and a permeability or face velocity of 7 feet/minute (3.56 cm/sec) at 0.5 inches (1.27 cm) of water pressure. The membrane is commercially available in finished filter form from W. L. Gore and Associates, Inc.

Additionally, PTFE is a non-linting, non-outgassing inert binder that can be used as an adsorbent binder by mechanically entrapping adsorbent particles within the PTFE material. This entrapment effectively reduces dusting of adsorbent material during the manufacture and during the life of the filter. This material can also be made in a relatively thin, highly loaded material as described in U.S. Pat. No. 4,985,296. The PTFE/adsorbent composite can be made in thicknesses from less than 0.001″ to 0.400″ or more. This allows a great deal of flexibility in finished filter thicknesses and adsorbent loading. Additionally, sorbent densities approximating 80-95% of full density are possible with multi-model packing and physical compression, so that maximum adsorbent material can be packed per unit volume. Unlike binders such as acrylics, melted plastic resins, etc., PTFE does not block the adsorbent pores.

The present invention provides a compact, clean, low outgassing (i.e., typically less than 20,000 ng/g at 85° C. for four hours), low particulating (i.e., typically less than 50 one hundred micron sized particle per square centimeter when tested with a liquid particle counter), unitary adsorbent breather filter and also, optionally, can be washable, particularly if the filter comprises hydrophobic PTFE membranes. The invention can utilize any suitable adsorbent type and be tailored for preferential performance in filtering of air from both internal and external sources for particles as well as hazardous vapor contaminants. As a single unit, the multi-functional filter minimizes installation time, as compared to the use of several conventional parts to achieve the required filtration and adsorption. The filter can further be combined with an optional diffusion tube to improve the performance of the breather component. The filter can still further be combined with a gasket to provide a means of sealing the disk drive. The multi-functional filters of the present invention can be used in filters where air is driven by normal convection, by diffusion means, by an auxiliary fan, or some combination thereof.

A diffusion tube can be included with the adsorbent breather filter as described in U.S. Pat. No. 5,417,743 by Dauber and U.S. Pat. No. 5,997,614 by Tuma et. al. Diffusion tubes provide additional protection against vaporous contaminants (including moisture) entering the drive through the breather opening by providing a diffusion barrier in the form of the diffusion tube which creates a tortuous or a longer path for contaminants to diffuse through before entering the drive enclosure. Diffusion tubes reduce the number of contaminants reaching the interior of the enclosure (and/or the adsorbent depending on the location of the filter) and increase the humidity time constants or time required to reach humidity equilibrium with the environment. As used herein, for convenience, the term “diffusion tube” may refer to either a conventional tortuous path or it may refer to a non-tortuous cavity into which incoming air passes before entering the filter.

The invention may be better understood with reference to the Figures, in which like parts have like numbering.

Referring to FIG. 1, there is shown a top perspective view of one embodiment of the multi-functional filter assembly 40 of the present invention as it would appear looking down on the filter mounted to an interior wall of a drive enclosure housing 41.

FIG. 2 shows a side cross-sectional view of another embodiment of a filter assembly 40 of the present invention as it would appear mounted on a disk drive enclosure housing 41. The air stream path is indicated as 21. The mounting adhesive layer 42 mounts the filter assembly 40 to the housing 41 and has a hole or opening 45 to allow the air to flow into and through the mounting adhesive layer 42. Layer 44 is the filter media. Layer 43 is a single layer adsorbent. A second optional filter media layer 26 is located such that the filter media encapsulates the adsorbent 43. Such a construction is desirable for adsorbents that may particulate because the filter media prevents such particulation from entering the drive during installation. Moreover, if the filter media is hydrophobic, the filter is washable. A pattern of adhesive strips is coated onto the adsorbent top surface as shown in layer 28. A patten of adhesive strips on bottom surface is shown as layer 29.

FIG. 3 shows additional features of a computer hard disk drive into which the filter assembly of FIG. 1 has been incorporated. Additional components typically present within a drive are shown, such as the rotating magnetic recording disks 11, the read/write heads 12 and the armatures 13 for moving the heads. The rotating disks 11 are the driving force for circulating, or recirculating, air within the disk drive.

FIGS. 4A and 4B show a side cross-sectional and top view respectively of one embodiment of the invention having flow layers adjacent to multiple surfaces of the adsorbent media, here shown as adjacent to the top and bottom surfaces. As shown in FIG. 4A, the filter 40 comprises a layer of mounting adhesive 42 with a hole 45 cut through it. A flow layer 46 is disposed between the mounting adhesive layer 42 and the bottom surface of adsorbent layer 43. A second flow layer 47 is adjacent to the top surface of the adsorbent, between the adsorbent layer 43 and the filtration layer 44. As used herein, the bottom refers to the side closest to or facing the opening. The top refers to the surface opposite the bottom. Filtration layer 44 encapsulates the adsorbent and the flow layer between the mounting adhesive 42 and the filtration layer 44. The filtration layer 44 is adhered to the mounting adhesive layer 42.

It should be apparent to one of skill in the art that the mounting adhesive may comprise a pressure sensitive adhesive layer, a double-sided adhesive tape on a backer material or multiple sided adhesive on multiple backers, depending on the desired construction of the filter. The mounting adhesive may also comprise a heat sensitive or UV or other curable adhesive layer. The mounting adhesive may also be a thermoplastic or thermoset material that will be able to mount to the enclosure surface. The hole 45 is aligned with a hole in the enclosure, such that air will enter the drive housing through the enclosure hole and the hole 45 in the mounting adhesive layer 42. The air will then pass along or through the flow layer 46, and either pass through the filter layer 44 or along the sides of the adsorbent media and then further along or through the flow layer 47 adjacent to the top surface of the adsorbent media, before passing through the filter media 44.

FIGS. 5A and 5B show side cross-sectional and top view respectively, of another embodiment of the filter assembly 40 where there are flow layers adjacent to the bottom and side surfaces of the adsorbent. The flow layers here are flow layers 46 adjacent to the bottom surface of the adsorbent layer 43 and flow layer 48 around the sides of the adsorbent layer 43.

FIGS. 6A and 6B show side cross-sectional and top views respectively of another embodiment with flow layers adjacent to the top, bottom, and side surfaces of the adsorbent. Again the layers are defined similarly to the way they were defined for FIGS. 4A and 4B and 5A and 5B respectively.

FIGS. 7, 8, 9, and 10 show a few of the possible patterns of flow layers useful in embodiments where the flow layer comprises a non-porous material having interstices or grooves therein to improve filter airflow. These by no means exhaust the possibilities, but are shown for illustrative purposes.

FIGS. 11A and 11B show a side cross-sectional view and a top view of another embodiment of the present invention where a diffusion tube is included with the adsorbent breather filter 40. Layers 30, 31, and 32 are a double-sided adhesive where layers 30 and 32 are adhesive coated onto the carrier layer 31. The adhesive layers 30, 31, and 32 have a hole or slot 35 cut through them that will be aligned at one end with a hole 36 in the disk drive enclosure wall 41. Layers 33 and 34 are single sided adhesive layers with layer 34 being the adhesive on a carrier layer 33 and is superimposed over layer 32 with hole 37 cut through it and superimposed over the end portion of hole or slot 35 which is opposite the end that is aligned over hole 36. Adsorbent layer 43 in this case has a flow layer 47 adjacent to the top surface, and a flow layer 46 adjacent to the bottom surface. The adsorbent layer 43 is superimposed over hole 37 and extends further over part of layer 34. Layer 44 is a filter layer, such as of a high efficiency membrane for good breather filtration efficiency, which covers adsorbent layer 43 and is adhered to adhesive layer 34

FIG. 12 is a side cross-sectional view of another embodiment of the present invention that is an outside mount version of the invention. Here filter 40 mounts on the outside of the enclosure wall 41 instead of the inside as previously shown. Layer 42 is a mounting adhesive layer that may be only adhesive or a double sided adhesive layer as previously detailed that has hole 56 cut through it and is placed over the vent hole 45 of the enclosure wall 41. Filter layer 53 is against the adhesive layer 42 and may be laminated or adhered to the adsorbent layer 43 and filters incoming air of particulates, can perform as a flow layer, and contains the adsorbent particles from entering the drive. Adsorbent layer 43 is shown with a flow layer 57 adjacent to its top surface. Layer 52 is an air impermeable layer that protects the carbon from the environment and contains the carbon to remove contaminates from the air within the drive and the air passing through hole 55 in the impermeable layer 52. The hole 55 may be offset from holes 45 and 56, but need not be. The outside mount filter is shown here as mounting on a flush enclosure wall 41, but the enclosure wall 41 could also be recessed and the filter mounted such that when installed, the filter outside surface may be flush with the outside wall surface. In such cases, it may be possible to have the impermeable layer 52 optionally mounted on the outer wall surface instead of the filter itself. Furthermore optional filter layers may be inserted such as between the adsorbent layer 43 and the impermeable layer 52 if desired placement of the layers or by use of lamination of layers together or by using additional adhesive or adhesive layers.

FIGS. 13A and 13B are side cross-sectional and top views respectively of an additional embodiment of the present invention where the filter is mounted on the outside of the enclosure wall similar to the FIG. 12 embodiment, but also has built in diffusion tube characteristics similar to the FIGS. 11A and 11B embodiments. Filter 40 is applied to the outside or enclosure surface 41. Mounting adhesive layer 42 again can be a layer of adhesive or a double sided adhesive layer with hole 56 cut in it and applied such that hole 56 aligns with hole 45 in the enclosure wall 41. Filter layer 53 is against the mounting adhesive layer 42 to filter the incoming air of particulates, perform as a flow layer, and contain carbon particles from the adsorbent layer 43, which in this illustration has flow layer 47 adjacent to its top surface. Layer 58 is an impermeable layer over the adsorbent layer 43. It could optionally have adhesive on either side for aiding assembly of the filter. For instance if it has adhesive on the side facing mounting adhesive layer 42, then mounting adhesive layer 42 could have optionally been a single sided adhesive. Hole 64 is cut through the impermeable layer 58 to allow airflow to pass from the exterior to the carbon and eventually into the enclosure. Layers 59, 60, and 61 are a double-sided adhesive with layers 59 and 61 being adhesive on both sides of the carrier 60. Hole or slotted hole 62 is cut through layers 59, 60, and 61 and aligns at one end with hole 64 through the impermeable layer 58. Impermeable layer 57 then is placed on layer 61. Optionally layer 61 could be an adhesive layer on the impermeable layer 57 and layers 59 and 60 could have been a single sided adhesive, again showing flexibility of construction possibilities. Hole or slot 62 aligns at one end with hole 63 cut in the impermeable layer 57 and at the opposite end with hole 64.

FIG. 14 is a side cross-sectional view of an alternative embodiment of the present invention with a recirculation filter included as part of the construction. The construction of this illustration is the same as was used in FIGS. 4 and 4A except that another filter layer 67 is placed over filter layer 44. Filter layer 67 is typically a more open layer to allow more airflow through the layer to have increased performance to clean air passing through it of particles. As the disks inside a drive spin, air is recirculated around inside the drive and such open filtration layers are typically used as a recirculation filter to clean the inside of the enclosure of particles. Optionally layers 44 and 67 could be combined into a single layer that is both open enough to allow recirculating air to flow through it to clean it of particles and efficient enough to clean the incoming air sufficiently of particles. One possible media of construction for layer 67 is an electret material such as that made by 3M company.

FIG. 15 is a side cross-sectional view of another embodiment of the present invention which is similar to that shown in FIGS. 4 and 4A, where now a filler or gasket 81 is placed over the filter that is countersunk into the enclosure wall such that the resultant filter and gasket are flush mounted into the enclosure. This can be of value to minimize the filter's disturbance to airflow and to minimize the space the filter takes up inside the enclosure. Both these can be important particularly for high revolution per minute Disk Drives and for very small Disk Drives.

FIGS. 16A and 16B are cross-sectional and top views respectively of another embodiment of the invention similar to FIGS. 4A and 4B, except where the adsorbent layer 43 has a perimeter top groove.

FIGS. 17A and 17B are cross-sectional and top views respectively of a further embodiment of the invention again similar to FIGS. 4A and 4B where the adsorbent layer 43 is replaced by multiple adsorbent layers, in this case layers 82 and 83 with a flow layer 49 disposed between them.

It should be clear to one skilled in the art that these illustrations are by no means exhaustive in how such a filter can be assembled and how combinations of the various filter enhancements can be combined in the filter construction.

Different materials can also be used as the impermeable layer shown in FIGS. 12 and 13. Polymer layers such as polyester, polypropylene or the like can be used as well as metallized polymer layers such as a metallized polyester. A preferred impermeable layer is a layer of thin aluminum. More preferably the impermeable layer is dead soft aluminum because it is impermeable, formable, and provides a good electromagnetic shield. For example, a 0.003″ thick dead soft aluminum layer as sold by ALL FOILS Brooklyn Heights, Ohio, is appropriate for use in the invention.

TEST PROCEDURES

Airflow Test:

Airflow was tested by making a fixture where the filter of the invention could be adhered over a hole in the fixture. The size of the hole in the fixture was 0.08″ (0.203 cm) in diameter. Air was delivered to the back side of the filter through a port (to allow air to flow through the hole in the mounting adhesive and through the filter). Another port on the fixture was placed to measure back pressure or the pressure required to flow a given volume of air through the filter. The filters were all tested at an airflow rate of 30 ml/min. Various filter constructions could then be tested and compared for airflow

Without intending to limit the scope of the present invention, the following examples illustrate how the present invention may be made and used.

EXAMPLES

Samples were made to test for resistance to airflow. The samples were all made using a commercially available double-sided acrylic adhesive from Adhesive's Research in Glenn Rock, Pa. The adsorbent was an adsorbent filled PTFE previously mentioned and made in accordance to U.S. Pat. No. 4,985,296. Some were compressed to form grooves in the adsorbent. Each adsorbent contained approximately 240 mg of activated carbon and was placed on a layer of adhesive. The filter layer was a 0.2 micron rated PTFE membrane as made and supplied in finished filters by W. L. Gore and Associates, Newark Del. The filter layer covered the adsorbent and was bonded to the adhesive layer at the perimeter of the adsorbent.

The following samples were made: Comparative Example 1 was constructed with grooves in the adsorbent on only the bottom side of the adsorbent; Inventive Example 1 had a flow layer consisting of a 30 gm/m² electret on only the bottom side of the adsorbent (without grooves); Inventive Example 2 had a flow layer made from strips of the double-sided adhesive on the bottom side of the adsorbent (without grooves) only. Additional samples were made in which a layer of the 30 gm/m² electret flow layer was added to the top of the adsorbent layer of each of the above constructions such that Inventive Example 3 had an adsorbent with grooves on the bottom and the electret flow layer on top; Inventive Example 4 had electret flow layers on the top and bottom of the adsorbent (without grooves) and Inventive Example 5 had strips of the double-sided adhesive on the bottom side of the adsorbent (without grooves) and an electret flow layer on top. Finally, Inventive Example 6 was constructed with a flow layers made from strips of the double-sided adhesive on both the top and bottom of the adsorbent (without grooves) media. The examples were then compared for airflow performance.

The filters were placed on the airflow test fixture and tested in accordance with the procedures previously outlined above. The results are contained in Table 1.

TABLE 1 Airflow Resistance Example Top Surface Bottom Surface (mm H₂O) Comparative No Layer Grooves 26.1 Example 1 Inventive Example 1 No Layer Electret 9.5 Flow Layer Inventive Example 2 No Layer Adhesive Strips 26.7 Inventive Example 3 Electret Flow Layer Grooves 4.0 Inventive Example 4 Electret Flow Layer Electret 7.4 Flow Layer Inventive Example 5 Electret Flow Layer Adhesive Strips 2.4 Inventive Example 6 Adhesive Strips Adhesive Strips 17.6

It is clear that the flow layers significantly reduced the pressure required to force the air through the filters, thereby enhancing their performance.

While particular embodiments of the present invention have been illustrated and described herein, the present invention should not be limited to such illustrations and descriptions. It should be apparent that changes and modifications may be incorporated and embodied as part of the present invention within the scope of the following claims: 

1. An adsorbent breather assembly for removing contaminants within an enclosure having a fluid inlet/outlet port comprising: a) an adhesive layer; b) an adsorbent media having at least a bottom surface adjacent to the adhesive layer and a top surface, the adsorbent media in fluid communication with the fluid inlet/outlet port; c) a porous flow layer having interstices that allow passage of a gas therethrough adjacent at least the top surface of the adsorbent media; and d) a filter media disposed over said porous flow layer and attached to the adhesive layer such that the adsorbent media and the flow layer are encapsulated between the adhesive layer and the filter media.
 2. The adsorbent breather assembly of claim 1, wherein the filter media comprises a porous polymeric membrane.
 3. The adsorbent breather assembly of claim 2, in which the filter media is hydrophobic.
 4. The adsorbent breather assembly of claim 2, wherein the filter media comprises PTFE.
 5. The adsorbent breather assembly of claim 2, further comprising an electret particle filtering layer disposed on the porous polymeric membrane.
 6. The adsorbent breather assembly of claim 1, wherein the filter media comprises an electret filter media.
 7. The adsorbent breather assembly of claim 1, in which the adsorbent media comprises PTFE and an adsorbent material.
 8. The adsorbent breather assembly of claim 7, in which the adsorbent media comprises a PTFE membrane filled with an adsorbent material.
 9. The adsorbent breather assembly of claim 1, in which the adsorbent media is molded.
 10. The adsorbent breather assembly of claim 1, in which the adsorbent media is a non-woven fabric impregnated with an adsorbent material.
 11. The adsorbent breather assembly of claim 1, in which the adsorbent media is a granular adsorbent material disposed on at least one side of a fiber scrim.
 12. The adsorbent breather assembly of claim 1, in which the adsorbent comprises a physisorbent.
 13. The adsorbent breather assembly of claim 12, in which the physisorbent is selected from the group consisting of activated carbon; activated alumina; molecular sieves; silica gel and combinations thereof.
 14. The adsorbent breather assembly of claim 1, in which the adsorbent media comprises a chemisorbent.
 15. The adsorbent breather assembly of claim 14, in which the chemisorbent comprises a material impregnated with at least one material selected from the group consisting of potassium permanganate, calcium carbonate, potassium carbonate, potassium hydroxide, sodium carbonate and calcium sulfate; and combinations thereof.
 16. The adsorbent breather assembly of claim 1, further comprising a flow layer adjacent to the bottom surface of the adsorbent media.
 17. The adsorbent breather assembly of claim 1 in which the flow layer is porous.
 18. The adsorbent breather assembly of claim 1 in which the flow layer comprises a discontinuous pattern of adhesive.
 19. The adsorbent breather assembly of claim 1 in which the flow layer is about 0.5 mils to about 50 mils thick.
 20. The adsorbent breather assembly of claim 1 in which the flow layer is about 10 mils to about 25 mils thick.
 21. The adsorbent breather assembly of claim 1 in which the flow layer is about 10 mils to about 20 mils thick.
 22. The adsorbent breather assembly of claim 1, in which the adhesive layer comprises an adhesive selected from the group consisting of at least: pressure sensitive adhesives, UV cured adhesives, hot-melt adhesives, ultrasonically activated polymers, cold temperature adhesives and epoxies.
 23. The adsorbent breather assembly of claim 1 further comprising: a) an impermeable layer covering the filter media and b) an enclosure, in which said adsorbent assembly is mounted to the outside of the enclosure.
 24. The adsorbent breather assembly of claim 1, further comprising a diffusion channel defined within the breather, the diffusion channel adapted to define a pathway for fluid communication between the port and the adsorbent.
 25. The adsorbent breather assembly of claim 1, wherein said at least one flow layer is adjacent to the bottom surface of the adsorbent media.
 26. A method of removing contaminants from an enclosure comprising the steps of: a) providing an enclosure defining a volume and having a fluid inlet/outlet port; b) providing an adhesive layer adjacent to the enclosure; c) providing an adsorbent having a bottom surface adjacent to the adhesive layer, a top surface opposite the bottom surface and at least one side surface, the adsorbent in fluid communication with the inlet/outlet port and the sealed volume; and d) providing a porous flow layer having interstices that allow passage of a gas therethrough adjacent to at least the top surface of the adsorbent media; and e) providing a filter media disposed over said porous flow layer and attached to the adhesive layer such that the adsorbent and the flow layer are encapsulated between the adhesive layer and the filter media.
 27. An adsorbent breather assembly for removing contaminants within an enclosure having a fluid inlet/outlet port comprising: a) adhesive layer; b) adsorbent media adjacent to the adhesive layer, said adsorbent media having at least a bottom surface, a side surface and a top surface, the adsorbent media in fluid communication with the fluid inlet/outlet port; c) flow layer adjacent at least one side surface of the adsorbent media; and d) filter media attached to the adhesive layer such that the adsorbent media and the flow layer are encapsulated between the adhesive layer and the filter media.
 28. An adsorbent breather assembly for removing contaminants within an enclosure having a fluid inlet/outlet port comprising: a. adhesive layer; b. adsorbent media adjacent to the adhesive layer, said adsorbent media having at least a bottom surface and a top surface, the adsorbent media in fluid communication with the fluid inlet/outlet port; c. flow layer comprising an impermeable layer having intersecting grooves on at least one surface, the flow layer being adjacent to the adsorbent media; and d. filter media attached to the adhesive layer such that the adsorbent media and the flow layer are encapsulated between the adhesive layer and the filter media.
 29. An adsorbent breather assembly for removing contaminants within an enclosure having a fluid inlet/outlet port comprising: a. adhesive layer; b. adsorbent media adjacent to the adhesive layer, said adsorbent media comprising at least two adsorbent layers, the adsorbent media in fluid communication with the fluid inlet/outlet port; c. at least one flow layer between adsorbent layers; and d. filter media attached to the adhesive layer such that the adsorbent media and the flow layer are encapsulated between the adhesive layer and the filter media. 